Connector

ABSTRACT

There is provided a connector for an endoscope that is easy to grip and is easily connected to a light source device. The connector includes: a light guide part, a wireless communication unit, a wireless power receiving unit, a housing section which houses the wireless communication unit and the wireless power receiving unit and in which the light guide part protrudes from a front surface thereof positioned close to a light source device in a connection posture where the connector is connected to the light source device, and a grip section that includes a concave finger placing portion on which a thumb is placed and which is provided on an upper surface thereof on a central axis of the light guide part in a case in which the grip section is viewed from an upper surface of the connector positioned on a vertically upper side in the connection posture.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application claims priority under 35 U.S.C. §119 to JapanesePatent Application No. 2015-122439, filed on Jun. 17, 2015. Each of theabove application(s) is hereby expressly incorporated by reference, inits entirety, into the present application.

BACKGROUND OF THE INVENTION 1. Field of the Invention

The present invention relates to a connector of an endoscope that isconnected to a light source device generating illumination light.

2. Description of the Related Art

A diagnosis, which uses an endoscope system including an endoscope, alight source device, and a processor device, is generally made in amedical field. The endoscope includes an insertion part that is insertedinto a subject, and images an observation object (a mucous membrane orthe like present in the subject) that is irradiated with illuminationlight generated by the light source device. The processor devicegenerates the image of the observation object by using image signalsthat are obtained from the imaging of the observation object, anddisplays the image of the observation object in a monitor.

The endoscope is connected to the light source device and the processordevice by a cable that is called a universal cable. The universal cableextends from an operation part (a grip section) of the endoscope, and aconnector, which is to be connected to the light source device and theprocessor device, is provided at an end portion of the universal cable.In a system in which a light source device and a processor device areseparately formed as in endoscope systems disclosed in JP2008-043450Aand JP2012-125401A, a connector includes a connector (hereinafter,referred to as an optical connector) from which a light guide (a lightguide part) for guiding illumination light generated by the light sourcedevice protrudes and which allows insertion of the light guide into thelight source device to optically connect the light guide to the lightsource device, and a connector (hereinafter, referred to as anelectrical connector) that is electrically connected to the processordevice by an electrical contact for sending and receiving controlsignals, image signals obtained from imaging performed by the endoscope,and the like. For example, the electrical connector is provided so as tobranch from the optical connector. Further, a connector in which anoptical connector and an electrical connector are integrated with eachother is used in a system in which a light source device and a processordevice are integrated with each other as in JP2013-208187A,JP2013-158425A, and JP2007-097691A.

Furthermore, there is a case in which the connector is provided with awireless sending portion for wirelessly sending image signals and apower receiving portion for receiving power to be supplied in anon-contact manner (JP2013-208187A).

SUMMARY OF THE INVENTION

As in JP2008-043450A, JP2012-125401A, JP2013-208187A, JP2013-158425A,JP2007-097691A, and JP2013-013648A, the light guide (an end portion ofan unbundled optical fiber in JP2013-013648A) protrudes from the endface of the connector for the endoscope. For this reason, when theconnector is to be connected to the light source device, there is a casein which the light guide is damaged by colliding with the light sourcedevice without being correctly inserted into a hole of the light sourcedevice into which the light guide is to be inserted according to thedirection, the angle, or the like of the connector. Accordingly, whenconnecting the connector to the light source device, it is necessary tocarefully connect the connector to the light source device whilechecking whether or not a connection position and an angle are correct.

When the light guide is damaged, a defect in which the observationobject is darkened or the like is generated due to the deterioration ofthe efficiency of the guiding of illumination light. Accordingly, inrecent years, a connector has been required to be formed in a shape thatis easier to grip than the connector in the related art so that theconnector is easily connected to the light source device.

For example, since the connectors disclosed in JP2008-043450A andJP2012-125401A can be gripped at substantially an arbitrary orientationand angle without having a designated manner of gripping, theorientation and angle of the connector with respect to the light sourcedevice needs to be adjusted by changing the grip or the like of theconnector whenever the connector is connected to the light sourcedevice. For this reason, in the cases of the connectors disclosed inJP2008-043450A and JP2012-125401A, there is room for making theconnector able to be more easily gripped for easy connection of theconnector to the light source device.

Each of the connectors disclosed in JP2013-208187A, JP2013-158425A, andJP2007-097691A has the shape of a rectangular parallelepiped of which atip portion close to the light source device is large, and has an Lshape where a portion to be connected to the universal cable protrudesfrom the tip portion of the rectangular parallelepiped. Further,considering positions where slip stoppers are provided and consideringthat connection terminals to be connected to a water supply tank and thelike provided in the vicinity thereof protrude, a root portion formed tobe thin needs to be held by being picked up from the upper and lowersides. For this reason, since the root portion is unstable, it isdifficult to accurately control a position where the light guide isinserted. Further, a method of gripping a large rectangularparallelepiped-shaped portion, which is close to the light sourcedevice, from the left and right sides to hold an L-shaped connector hasalso been considered, but it is difficult to accurately control theposition of the light guide in the vertical direction and the insertionangle of the light guide in this method.

Furthermore, notches are formed on the outer surface of the cylindricalconnector disclosed in JP2013-013648A, but the surface on which thenotches are formed are the side surfaces of the connector. For thisreason, in a case in which the connector is naturally held using thenotches, the connector is picked up by fingers so as to be covered fromthe upper surface and is held in a direction perpendicular to the arm.Accordingly, considering the movable range of a wrist, or the like, itis difficult to connect the connector while positioning the light sourcedevice in front and checking a connection position.

An object of the invention is to provide a connector that is easier togrip than a connector in the related art and is easily connected to alight source device.

There is provided a connector for an endoscope that is connected to alight source device generating illumination light. The connectorcomprises a light guide part that guides the illumination light, awireless communication unit that wirelessly communicates with the lightsource device, a wireless power receiving unit that receives powerwirelessly supplied from the light source device, a housing sectionwhich houses the wireless communication unit and the wireless powerreceiving unit and in which the light guide part protrudes from a frontsurface thereof positioned close to the light source device in aconnection posture where the connector is connected to the light sourcedevice, a grip section that includes a concave finger placing portion onwhich a thumb is placed and which is provided on a central axis of thelight guide part in a case in which the grip section is viewed from anupper surface of the connector positioned on a vertically upper side inthe connection posture, and a finger locking portion that is providedbetween the housing section and the grip section and locks a forefingeron a lower surface of the connector and on the rear of the wirelesspower receiving unit in the connection posture.

It is preferable that a central axis of the grip section is coincidentwith a central axis of the light guide part in a case in which theconnector is viewed from the upper surface thereof in the connectionposture.

It is preferable that the central axis of the light guide part is offsetto the upper surface of the connector in the connection posture withrespect to the central axis of the grip section.

It is preferable that the housing section is capable of housing thewireless communication unit and the wireless power receiving unit on aside thereof close to a lower surface of the connector positioned on avertically lower side in the connection posture.

It is preferable that the grip section has a shape in which across-sectional area decreases toward a rear portion thereof opposite tothe housing section from a front portion thereof, which is close to thehousing section, in the connection posture.

It is preferable that a lower surface of the housing section, which ispositioned on the vertically lower side in the connection posture, is aflat surface.

It is preferable that an upper surface of the housing section, which ispositioned on the vertically upper side in the connection posture, is acurved surface.

It is preferable that the wireless communication unit is capable ofperforming near-infrared communication between the light source deviceand itself.

It is preferable that a front surface of the connector where thewireless power receiving unit receives power supplied from the lightsource device has a structure in which a gap is formed between the frontsurface of the connector and a contact surface of the light sourcedevice in a case in which the connector is connected to the light sourcedevice.

It is preferable that the housing section houses the wireless powerreceiving unit so that the wireless power receiving unit comes intocontact with the upper surface of the connector in the connectionposture and the wireless power receiving unit receives power suppliedfrom the light source device through the upper surface of the connectorin the connection posture.

It is preferable that in a case in which the light source deviceincludes an upper flange portion that holds the upper surface of theconnector in the connection posture and the wireless power receivingunit is capable of receiving power to be supplied through the upperflange portion.

It is preferable that the central axis of the light guide part iscoincident with the central axis of the grip section in a case in whichthe connector is viewed from a left side surface or a right side surfacethereof in the connection posture.

The connector of the invention is easier to grip than a connector in therelated art and is easily connected to a light source device.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a view showing the appearance of an endoscope system.

FIG. 2 is a perspective view showing the appearance of a connector.

FIG. 3 is a front view of the connector.

FIG. 4 is a front view of the connector that is placed on a table or thelike.

FIG. 5 shows a top view and a sectional view of a finger placingportion.

FIG. 6 is a top view of the connector.

FIG. 7 is a side view of the connector.

FIG. 8 is a perspective view of the connector that is gripped with theright hand.

FIG. 9 is a side view of the connector that is gripped with the righthand.

FIG. 10 is a perspective view of a light source device.

FIG. 11 is a side view of a connection section to which the connector isconnected.

FIG. 12 is a perspective view of the connector that includes a wirelesspower receiving unit on the upper surface thereof.

FIG. 13 is a side view of the connector of which the central axis of alight guide part and the central axis of a grip section are coincidentwith each other.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

As shown in FIG. 1, an endoscope system 10 includes an endoscope 12, alight source device 14, a processor device 16, a monitor 18, and aconsole 20. The endoscope 12 includes an insertion part 21 that isinserted into a subject, an operation part 22 that is provided at thebase end portion of the insertion part 21, and a universal cable 23. Theuniversal cable 23 is a cable in which a light guide part 31 (see FIG.2) for guiding illumination light emitted from the light source device14, a control line for controlling an imaging sensor provided at the tipof the insertion part 21, a signal line for sending image signals outputfrom the imaging sensor during the imaging of an observation objectirradiated with the illumination light, a power line for supplying powerto each part such as the imaging sensor, and the like are integratedwith each other. The universal cable 23 extends from the base endportion of the operation part 22, and a connector 25 connected to thelight source device 14 is provided at the tip of the universal cable 23.Further, the light guide part 31 of the endoscope 12 is a light guidethat is a bundle of optical fibers.

The light source device 14 generates illumination light by asemiconductor light source, such as a LED (Light Emitting Diode) or a LD(Laser Diode), or a halogen lamp such as a xenon lamp. In a case inwhich the connector 25 is connected to the light source device 14,illumination light is incident on the light guide part 31 of theconnector 25 and is applied to an observation object from the tip of theinsertion part 21.

Further, the light source device 14 is electrically connected to theprocessor device 16, and the connector 25 of the endoscope 12 isconnected to the processor device 16 through the light source device 14.The sending and receiving of control signals, image signals, and thelike between the light source device 14 and the connector 25 arewireless communication. For this reason, the light source device 14transmits control signals and the like, which are wirelessly sent to andreceived from the connector 25, to the processor device 16. Furthermore,the light source device 14 supplies power, which is used to drive theimaging sensor and the like, to the connector 25, but the supply of thispower is also performed wirelessly.

The processor device 16 controls the amount and light emitting timing ofillumination light emitted from the light source device 14, theoperation of the imaging sensor, and the like, and generates anendoscopic image by using image signals that are obtained from theimaging of the observation object that is irradiated with theillumination light. Further, the processor device 16 is electricallyconnected to the monitor 18 and the console 20. The monitor 18 displaysthe endoscopic image generated by the processor device 16, informationabout the endoscopic image, and the like. The console 20 is a userinterface that receives an input operation, such as function setting.

As shown in FIG. 2, the connector 25 includes a housing section P1, agrip section P2, and an intermediate section P3. Further, the connector25 includes a plurality of connection terminals 29 a to 29 f that areconnected to devices and the like other than the light source device 14.Hereinafter, a posture where the connector 25 is correctly connected tothe light source device 14 arranged horizontally is referred to as a“connection posture”, a connection direction in which the connector 25is connected to the light source device 14 in the connection posture isreferred to as a Z direction, the vertical direction of the connector 25in the connection posture is referred to as a Y direction, and adirection, which is in a horizontal plane perpendicular to the Zdirection and the Y direction, is referred to as an X direction. Thepositive side in the Z direction is a side where the light source device14 is positioned when viewed from the connector 25; the positive side inthe Y direction is a vertically upper side; and the positive side in theX direction is a left side when viewed toward the positive side from thenegative side in the Z direction.

In this case, the surface of the connector 25 in the connection posture,which is viewed from the vertically upper side, is an upper surface 41and the surface of the connector 25 in the connection posture, which isviewed from the vertically lower side, is a lower surface 42. Thesurface of the connector 25 in the connection posture, which is viewedfrom the positive side in the X direction, is a left side surface, andthe surface of the connector 25 in the connection posture, which isviewed from the negative side in the X direction, is a right sidesurface. The surface of the connector 25 in the connection posture,which is viewed from the positive side in the Z direction, is a frontsurface (or the front), and the surface of the connector 25 in theconnection posture, which is viewed from the negative side in the Zdirection, is a rear surface (or the back).

The housing section P1 houses a wireless communication unit 33 thatwirelessly communicates with the light source device 14 and a wirelesspower receiving unit 34 that wirelessly receives power supplied from thelight source device 14, and the light guide part 31 protrudes from thefront surface 32 that is positioned close to the light source device 14in the connection posture. Since a position at which the light guidepart 31 protrudes is close to the upper surface 41 that is positioned onthe vertically upper side in the connection posture, the housing sectionP1 houses the wireless communication unit 33 and the wireless powerreceiving unit 34 on a side thereof close to the lower surface 42positioned on the vertically lower side in the connection posture.

The front surface 32 is a surface on an XY plane perpendicular to the Zdirection and is also a tip surface of the connector 25. A pumpconnection portion 38 protrudes from the front surface 32 on thevertically lower side of the light guide part 31 in addition to thelight guide part 31. A pump (not shown), which is provided in the lightsource device 14, is connected to the pump connection portion 38 whenthe connector 25 is connected to the light source device 14. Further,the pump connection portion 38 is connected to a conduit, such as anair/water supply channel, communicating with the connector 25, theuniversal cable 23, the operation part 22, and the insertion part 21.Furthermore, a fitting protrusion 39, which is fitted to a fittingrecess 111 (see FIG. 10) provided on the light source device 14, isprovided at the base end portion of the light guide part 31 and the pumpconnection portion 38, and the fitting protrusion 39 also protrudes fromthe front surface 32. Since the light guide part 31 protrudes in the Zdirection so as to be longer than the fitting protrusion 39, the lightguide part 31 is visible when a user grips the connector 25. A centralaxis L_(LG) of the light guide part 31 and the protruding direction ofthe pump connection portion 38 are parallel to the Z direction.

As shown in FIG. 3, the light guide part 31 and the pump connectionportion 38 are disposed in the laterally middle of the front surface 32so as to be lined up in the Y direction. Further, the upper surface 41of the housing section P1, which is positioned on the vertically upperside in the connection posture, is a curved surface as shown by an arrowA1, and the lower surface 42 of the housing section P1, which ispositioned on the vertically lower side in the connection posture, is aflat surface as shown by an arrow A2. More specifically, the housingsection P1 has a so-called “hog-backed shape”. That is, the uppersurface 41 of the housing section P1 has the shape of a circular arcconvex toward the positive side in the Y direction in a case in whichthe upper surface 41 is viewed from the front surface 32, and has ashape maintaining a substantially constant height in the Z direction ina case in which the upper surface 41 is viewed from the right sidesurface or the left side surface. The light guide part 31 and the pumpconnection portion 38 are provided on the front surface 32 so as to beclose to the upper surface 41. In contrast, the wireless communicationunit 33 and the wireless power receiving unit 34 are provided on thefront surface 32 so as to be close to the lower surface 42 and be linedup laterally.

The wireless communication unit 33 includes: a control signalsending/receiving part 36 that wirelessly sends and receives controlsignals, which control the light source device 14, the imaging sensor,and the like, to and from the light source device 14; and an imagesignal sending part 37 that wirelessly sends image signals, which areobtained from the imaging of the observation object irradiated with theillumination light, to the light source device 14. Wirelesscommunication, which is performed by the control signalsending/receiving part 36 and the image signal sending part 37, isoptical communication, and it is preferable that the wirelesscommunication is, for example, near-infrared communication usingnear-infrared light (light having a wavelength in the range of about 0.7μm to 2.5 μm). A connection terminal of the control signalsending/receiving part 36 is formed substantially on the front surface32, and a connection terminal of the image signal sending part 37protrudes from the front surface 32 in parallel with the Z direction.

The wireless power receiving unit 34 is, for example, a coil (aso-called secondary coil), and receives power that is supplied from acoil (a so-called primary coil) of the light source device 14 by anon-contact power transmission method, such as an electromagneticinduction method or a magnetic field resonance method. In this case,since the wireless power receiving unit 34 is provided on the rear ofthe front surface 32, the wireless power receiving unit 34 receivespower supplied from the light source device 14 through the front surface32. The wireless power receiving unit 34 supplies power to each part ofthe endoscope 12 such as the imaging sensor.

When the connector 25 is connected to the light source device 14, thelight source device 14 locks the connector 25 at the upper surface 41and the lower surface 42 of the housing section P1. Accordingly, thelight source device 14 locks the connector 25 and maintains connection.For this purpose, the light source device 14 is provided with lockingmembers 108 (see FIG. 10), which are used to lock the connector 25, atthe positions thereon corresponding to the upper surface 41 and thelower surface 42 of the housing section P1. So as to correspond to thelocking members 108, a groove 43 to which the locking members 108 of thelight source device 14 are fitted is provided on the upper surface 41 ofthe connector 25 and a groove 44 to which the locking members of thelight source device 14 are fitted is provided on the lower surface 42 ofthe connector 25.

Further, a left ear portion 46 a, which protrudes toward the positiveside in the X direction, is provided on the left side surface of thehousing section P1, and a right ear portion 46 b, which protrudes towardthe negative side in the X direction, is provided on the right sidesurface of the housing section P1. That is, the housing section P1includes the left and right ear portions 46 a and 46 b, which protrudein the horizontal direction, on the side surfaces thereof between theupper and lower surfaces 41 and 42. Even though the connector 25 tiltswhen the connector 25 is placed on a table 47 or the like, the left earportion 46 a prevents the connection terminals 29 a to 29 c, which areprovided on the left side surface of the connector 25, from collidingwith the table 47 or the like as shown in FIG. 4. Likewise, even thoughthe connector 25, which is placed on the table 47 or the like, tilts,the right ear portion 46 b prevents the connection terminals 29 d to 29f, which are provided on the right side surface of the connector 25,from colliding with the table 47 or the like. Meanwhile, since the lowersurface 42 of the housing section P1 of the connector 25 is a flatsurface, it is difficult for the connector 25 to tilt in comparison witha case in which the lower surface 42 is a curved surface.

The grip section P2 is a rear end (a portion corresponding to thenegative side in the Z direction) of the connector 25, and is a portionthat is gripped by a user in a case in which the user connects theconnector 25 to the light source device 14 and a case in which the userremoves the connector 25 from the light source device 14. A concavefinger placing portion 51 on which the user places his thumb whengripping the connector 25 is provided on the upper surface 41 of thegrip section P2.

In a case in which the connector 25 is viewed from the upper surface 41,as shown in FIG. 5, the finger placing portion 51 includes asemi-circular front portion 56 that is close to the housing section P1,a rectangular middle portion 57 of which the longitudinal direction isparallel to the Z direction, and a semi-circular rear portion 58 that isclose to the universal cable 23; and is a stadium-shaped recess of whicha length Wz in a direction (a first direction) parallel to a centralaxis L_(grip) of the grip section P2 is longer than a length Wx in adirection (a second direction) orthogonal to the central axis L_(grip)of the grip section P2. The surface of the front portion 56, which isclose to the housing section P1, of the finger placing portion 51 isformed of a curved surface, and the front portion 56 is formed in ashape that gradually becomes shallow toward the housing section P1 fromthe middle portion 57 and the rear portion 58, which are provided on theside opposite to the housing section P1, as shown by an arrow A3. Forthis reason, the depth of the front portion 56 is reduced toward thehousing section P1 from the rear portion 58 (or the middle portion 57).Further, the depth of the front portion 56 of the finger placing portion51 is reduced as being distant from the middle even when viewed in the Xdirection. That is, the front portion 56 of the finger placing portion51 is formed in a shape that fits the shape of the tip of the thumbplaced on the finger placing portion 51. Meanwhile, the depth of thefront portion 56, the middle portion 57, the rear portion 58, or thefinger placing portion 51 is a depth from the upper surface 41 aroundthe finger placing portion 51.

Slip stoppers 59 are formed on the middle portion 57 of the fingerplacing portion 51. The slip stoppers 59 are elongated stadium-shapedprotrusions that are parallel to the X direction. When a thumb is placedon the finger placing portion 51, the slip stoppers 59 generate a forceresistant to the belly (a portion of the thumb on which fingerprints areformed) of the thumb in the Z direction. For this reason, it isdifficult for the thumb placed on the finger placing portion 51 to slipeven though a force is applied in the Z direction in a case in which theconnector 25 is connected to the light source device 14 or a case inwhich the connector 25 is removed from the light source device 14.Further, since the middle portion 57 of the finger placing portion 51has a depth substantially constant in the Z direction but has the shapeof a U-shaped surface curved in the X direction, the thumb is naturallyplaced in the middle of the finger placing portion 51 when the thumb isplaced on the finger placing portion 51.

Similar to the front portion 56, the rear portion 58 of the fingerplacing portion 51 is formed of a curved surface. However, on thecontrary to the front portion 56, the shape of the surface of the rearportion 58 becomes shallow from the middle portion 57 toward the rearend of the connector 25 to which the universal cable 23 is connected,and becomes shallow as being distant from the middle when viewed in theX direction.

Further, the entire shape of the grip section P2 is formed substantiallyin the shape of a cylinder that has a thickness easy to grip, and theuniversal cable 23 is connected to a rear portion P2E of the gripsection P2. A cover 52 covers a connection portion between the gripsection P2 and the universal cable 23, so that the rear portion P2E ofthe grip section P2 and the universal cable 23 are smoothly connected toeach other. Furthermore, a front portion P2F of the grip section P2 hasa substantially constant thickness. As shown by arrows A4 and AS of FIG.6 and arrows A6 and A7 of FIG. 7, the rear portion P2E of the gripsection P2 becomes narrow toward the rear portion where the universalcable 23 is positioned. That is, the grip section P2 has a shape where across-sectional area is reduced toward the rear portion P2E thereofopposite to the housing section P1 from the front portion P2F thereof,which is close to the housing section P1, in the connection posture.Further, the cross-section of the grip section P2, which isperpendicular to the central axis L_(grip), has a substantially circularshape regardless of a position in the Z direction. More specifically,the front portion P2F of the grip section P2 has a substantiallyconstant cross-sectional area, and the cross-sectional area of the rearportion P2E of the grip section P2 is reduced toward the negative sidein the Z direction where the universal cable 23 is connected. Forexample, when a cross-section CS1 shown in the front portion P2F by atwo-dot chain line is compared with a cross-section CS2 shown in therear portion P2E by a two-dot chain line, all of the cross-sections CS1and CS2 have a substantially circular shape but the area of thecross-section CS2 of the rear portion P2E is smaller than the area ofthe cross-section CS1 of the front portion P2F.

In a case in which the connector 25 is viewed from the upper surface 41,the central axis L_(grip) of the grip section P2 is coincident with thecentral axis L_(LG) of the light guide part 31 that protrudes from thefront surface 32 as shown in FIG. 6. Furthermore, the finger placingportion 51 is formed on the central axis L_(grip) of the grip section P2in a case in which the connector 25 is viewed from the upper surface 41.Meanwhile, in a case in which the connector 25 is viewed from the leftside surface as shown in FIG. 7 or in a case in which the connector 25is viewed from the right side surface, the central axis L_(LG) of thelight guide part 31, which protrudes from the front surface 32, isoffset to the upper surface 41 with respect to the central axis L_(grip)of the grip section P2.

In addition, the connection terminal 29 c is provided on the right sidesurface of the grip section P2 and the connection terminal 29 f isprovided on the left side surface of the grip section P2. The connectionterminal 29 a, the connection terminal 29 b, the connection terminal 29d, and the connection terminal 29 e, which are provided on the sidesurfaces of the connector 25, protrude from the connector 25, which isin the connection posture, in the horizontal direction (toward thepositive side or the negative side in the X direction), and theconnection terminals 29 c and 29 f, which are provided on the sidesurfaces of the grip section P2, protrude from the side surfaces of thegrip section P2 so as to be inclined toward the upper surface 41 fromthe horizontal direction by an angle φ (see FIG. 2). Meanwhile, theconnection terminal 29 a is a tank connector connected to a water supplytank, the connection terminal 29 c is a ventilation connector, theconnection terminal 29 d is a suction connector, and the connectionterminal 29 f is an S connector to which an S cord is connected when ahigh-frequency treatment tool such as an electric scalpel is used.

The intermediate section P3 is a portion that connects the housingsection P1 to the grip section P2. The shape of a portion of theintermediate section P3 close to the grip section P2 corresponds to theshape of the grip section P2, and the shape of a portion of theintermediate section P3 close to the housing section P1 corresponds tothe shape of the housing section P1. Since the cross-section of thehousing section P1 has a substantially hog-backed shape and thecross-section of the grip section P2 has a substantially circular shape,the intermediate section P3, which connects the housing section P1 tothe grip section P2, has a shape that is smoothly changed to ahog-backed shape from a circular shape toward the housing section P1from the grip section P2. For this reason, the upper surface 41 of theintermediate section P3 swells to the positive side in the Y directiontoward the housing section P1 from the grip section P2 as shown in FIG.7 by an arrow A8. Further, the lower surface 42 of the intermediatesection P3 includes a finger locking portion 61 that is concave to thepositive side in the Y direction toward the housing section P1 from thegrip section P2 as shown by an arrow A9. The finger locking portion 61is provided at a portion between the housing section P1 and the gripsection P2 where a forefinger reaches in a case in which the connector25 is gripped at the grip section P2; and locks the forefinger on thelower surface 42 in the connection posture and on the rear of thewireless power receiving unit 34. The finger locking portion 61 includesan inclined surface 62 that is inclined with respect to the central axisL_(grip) of the grip section P2, and the inclined surface 62 is a curvedsurface of which the inclination angle with respect to the central axisL_(grip) of the grip section P2 is gradually increased toward thehousing section P1 from the grip section P2.

Since the forefinger is locked to the finger locking portion 61 when auser naturally grips the connector 25, the forefinger is always spacedapart from the wireless power receiving unit 34 by a predetermineddistance. For this reason, the wireless power receiving unit 34 isheated when receiving power supplied from the light source device 14,but it is possible to prevent the forefinger from coming into contactwith the vicinity of the heated wireless power receiving unit 34 sincethe finger locking portion 61 is provided. Therefore, it is possible tosafely remove the connector 25 from the light source device 14.

When a user grips the connector 25 having the above-mentioned structurewith, for example, the right hand 80, the user grips the grip section P2while placing a thumb 81 on the finger placing portion 51 as shown inFIGS. 8 and 9. In this case, the back, the forefinger 82, a middlefinger 83, a ring finger 84, and a little finger 85 of the right hand 80wrap around the lower surface 42 while coming into contact with theright side surface of the connector 25. Further, the forefinger 82 isplaced on the finger locking portion 61 of the intermediate section P3and the thumb 81, the middle finger 83, the ring finger 84, the littlefinger 85, and a carpal region 86 grip the grip section P2. That is,since the grip section P2 of the connector 25 can be “gripped” bysubstantially the entire right hand 80, the connector 25 can be stablygripped and is easily connected to the light source device 14.

Particularly, when the thumb 81 is placed on the finger placing portion51, the connector 25 is substantially naturally gripped as describedabove. Accordingly, the posture of the connector 25, which is gripped,naturally becomes the connection posture. For this reason, since thefinger placing portion 51 is provided on the upper surface 41 of thegrip section P2, the connector 25 is more easily gripped and connectedto the light source device 14 than a connector of an endoscope in therelated art.

Furthermore, the cross-section of the grip section P2, which isperpendicular to the central axis L_(grip), has a substantially circularshape regardless of a position in the Z direction; the front portionP2F, which is close to the housing section P1, of the grip section P2has a substantially constant cross-sectional area; and thecross-sectional area of the rear portion P2E is reduced toward the rearend of the connector 25 that is positioned on the negative side in the Zdirection where the universal cable 23 is provided. Accordingly, thegrip of the connector fits the above-mentioned grip. For this reason,the connector 25 has a shape that is particularly easily gripped and iseasily connected to the light source device 14.

In addition, in a case in which a user grips the grip section P2 bysubstantially the entire right hand 80 while placing the thumb 81 on thefinger placing portion 51, an axis of a connection operation for movingthe gripped connector 25 to the light source device 14 is hardly shakenwhen the user additionally places the forefinger 82 on the fingerlocking portion 61. For this reason, the finger locking portion 61,which is formed on the lower surface 42 of the intermediate section P3,also improves stability during the gripping of the connector 25 and thestability of the connection operation for moving the connector 25 to thelight source device 14.

Moreover, since the upper surface 41 of the housing section P1 is formedof a curved surface having the shape of a circular arc, it is easy toconnect the connector 25 to the light source device 14. Specifically,since a vertex of the housing section P1 that seems to most protrude, asensory central axis (L_(grip)) of the right hand 80 that grips theconnector 25, and the light guide part 31 are lined up on a line when auser grips the connector 25 and views the upper surface 41 of thehousing section P1, there is a sense of unity as a whole. For thisreason, since the sense of position of the light guide part 31 does notdeteriorate according to an angle at which a user views the connector25, or the like, the connector 25 is easily connected to the lightsource device 14. Meanwhile, since the upper surface 41 of the housingsection P1 is formed of a curved surface having the shape of a circulararc, the housing section P1 saves space in comparison with a case inwhich the housing section P1 is formed in a rectangular parallelepipedshape.

A sense of direction in a case in which a user grips the connector 25depends on the direction of the thumb 81 that is placed on the fingerplacing portion 51. The connector 25 allows the central axis L_(LG) ofthe light guide part 31 to be offset to the upper surface 41 withrespect to the central axis L_(grip) of the grip section P2 so that thecentral axis L_(LG) of the light guide part 31 is close to the thumb 81.For this reason, since it is possible to more correctly grasp theposition of the light guide part 31 than a case in which the centralaxis L_(LG) of the light guide part 31 is distant from the thumb 81, theconnector 25 is easily connected to the light source device 14. Further,since the central axis L_(LG) of the light guide part 31 is offset tothe upper surface 41 in the connector 25, a space, which is used to formthe finger locking portion 61, is provided on the lower surface 42 ofthe intermediate section P3. For this reason, the offset of the centralaxis L_(LG) of the light guide part 31 to the upper surface 41 alsocontributes to the ease of the grip of the connector 25.

A sense of direction of the right hand 80, which grips the connector 25,also depends on the center of the grip, that is, the central axisL_(grip) of the grip section P2. Since the central axis L_(grip) of thegrip section P2 is coincident with the central axis L_(LG) of the lightguide part 31, which protrudes from the front surface 32, in a case inwhich the connector 25 is viewed from the upper surface 41, the sense ofdirection of the right hand 80, when the connector 25 is gripped,corresponds to the direction of the light guide part 31 (the centralaxis L_(LG)). For this reason, the connector 25 is easily connected tothe light source device 14.

Further, since the finger placing portion 51 is formed on the centralaxis L_(grip) of the grip section P2 in a case in which the connector 25is viewed from the upper surface 41, the direction of the thumb 81,which grips the connector 25, naturally becomes parallel to the centralaxis L_(grip) of the grip section P2. For this reason, since thedirection of the light guide part 31 is easily determined, the connector25 is easily connected to the light source device 14. Furthermore, sincethe finger placing portion 51 is formed of a stadium-shaped recess ofwhich the length Wz in a direction (the first direction) parallel to thecentral axis L_(grip) of the grip section P2 is longer than the lengthWx in a direction (the second direction) orthogonal to the central axisL_(grip) of the grip section P2, the direction of the thumb 81 is likelyto naturally become parallel to the central axis L_(grip) of the gripsection P2. Accordingly, the shape of the finger placing portion 51allows the connector 25 to be easily connected.

Meanwhile, since the connection terminals 29 c and 29 f, which areprovided on the side surfaces of the grip section P2, of the connector25 protrude from the side surfaces of the grip section P2 so as to beinclined toward the upper surface 41 from the horizontal direction by anangle φ (see FIG. 2), the connection terminals 29 c and 29 f do nothinder a user from gripping the grip section P2 with the right hand 80or the left hand when the user grips the connector 25. That is, theinclination of the connection terminals 29 c and 29 f, which areprovided on the side surfaces of the grip section P2, from thehorizontal direction allows the user to easily grip the connector 25.The connection terminal 29 c has been provided on the left side surfaceof the grip section P2 of the connector 25 and the connection terminal29 f has been provided on the right side surface thereof, but only oneof the connection terminals 29 c and 29 f may be provided or a pluralityof connection terminals may be provided on one side surface so as to beinclined toward the upper surface 41.

Meanwhile, as shown in FIG. 10, a power button 101, operation buttons102, and a display panel 103 are provided on the front surface of thelight source device 14 and a connection section 104 to which theconnector 25 is connected is provided on the right side of the frontsurface (the positive side in the X direction). The connection section104 includes an upper flange portion 106 and a lower flange portion 107that are provided at positions corresponding to the upper surface 41 andthe lower surface 42 of the connector 25 and protrude from the frontsurface of the light source device 14 toward the negative side in the Zdirection. Since the light source device 14 locks the upper and lowersurfaces 41 and 42 of the housing section P1 by the upper and lowerflange portions 106 and 107 of the connection section 104 when theconnector 25 is connected to the light source device 14, the lightsource device 14 maintains connection between the connector 25 anditself. For this purpose, the locking members 108, which lock theconnector 25, are provided on the inner surface of the upper flangeportion 106 that comes into contact with the upper surface 41 of theconnector 25 and the inner surface of the lower flange portion 107 thatcomes into contact with the lower surface 42 of the connector 25. Theupper and lower flange portions 106 and 107 of the connection section104 are holding portions that hold the connector 25 connected to theconnection section 104. Further, since the upper flange portion 106 hasthe shape of a curved surface corresponding to the upper surface 41 ofthe housing section P1 and the lower flange portion 107 has the shape ofa flat surface corresponding to the lower surface 42 of the housingsection P1, the upper and lower flange portions 106 and 107 alsofunction as a connection guide portion that guides the connector 25 in acorrect connection posture. The lower surface 42 of the housing sectionP1 of the connector 25 is a flat surface and the lower flange portion107 of the connection section 104 corresponding to the lower surface 42supports the connector 25 by a flat surface. Accordingly, even thoughthe universal cable 23 moves and a twisting force is applied around thecentral axis L_(LG) of the light guide part 31, the connection section104 stably holds the connector 25 without the application of a load tothe light guide part 31 and the like.

The fitting recess 111 to which the fitting protrusion 39 of theconnector 25 is fitted is formed on a front surface (hereinafter,referred to as a contact surface) 109 coming into contact with the frontsurface 32 of the connector 25, and a first hole portion 112 into whichthe light guide part 31 of the connector 25 is inserted and a secondhole portion 113 into which the pump connection portion 38 is insertedare further formed in the fitting recess 111.

Furthermore, a wireless communication unit 114 that wirelesslycommunicates with the wireless communication unit 33 of the connector 25and a wireless power supply unit 115 that supplies power to the wirelesspower receiving unit 34 of the connector 25 are provided on the rear ofa lower portion of the contact surface 109. The wireless communicationunit 114 includes: a control signal sending/receiving part 116 thatsends and receives control signals to and from the control signalsending/receiving part 36; and an image signal receiving part 117 thatreceives image signals from the image signal sending part 37. Aconnection terminal of the control signal sending/receiving part 116 isformed substantially on the contact surface 109, and a connectionterminal of the image signal receiving part 117 is formed of a holeportion into which the image signal sending part 37 is inserted. Thewireless power supply unit 115 is, for example, a coil (a so-calledprimary coil), and supplies power to the wireless power receiving unit34 by a non-contact power transmission method, such as anelectromagnetic induction method or a magnetic field resonance method.

The positions of the locking members 108 and the grooves 43 and 44 towhich the locking members 108 are fitted are determined so that a gap D1is formed between the front surface 32 of the connector 25 and thecontact surface 109 of the connection section 104 when the connector 25is connected to the connection section 104 as shown in FIG. 11. Whendust or the like is present between the wireless power supply unit 115and the wireless power receiving unit 34 during the supply of power tothe wireless power receiving unit 34 from the wireless power supply unit115, the dust or the like may generate heat. However, since the gap D1is formed between the front surface 32 and the contact surface 109, itis possible to prevent dust or the like from being interposed betweenthe wireless power supply unit 115 and the wireless power receiving unit34 and to safely supply power to the wireless power receiving unit 34from the wireless power supply unit 115.

Meanwhile, in the above-mentioned embodiment, the housing section P1 ofthe connector 25 has housed the wireless power receiving unit 34 on therear of the front surface 32 so that the wireless power receiving unit34 comes into contact with the front surface 32. However, instead ofthis, as in a connector 225 shown in FIG. 12, a housing section P1 mayhouse a wireless power receiving unit 34 so that a wireless powerreceiving unit 34 comes into contact with an upper surface 41, and thewireless power receiving unit 34 may receive power supplied from theupper surface 41. In this case, the connection section 104 of the lightsource device 14 includes the wireless power supply unit 115 on theupper flange portion 106, and power is supplied to the wireless powerreceiving unit 34 from the wireless power supply unit 115 through theupper flange portion 106.

In the above-mentioned embodiment, in a case in which the connector 25is viewed from the left side surface or in a case in which the connector25 is viewed from the right side surface, the central axis L_(LG) of thelight guide part 31, which protrudes from the front surface 32, has beenoffset to the upper surface 41 with respect to the central axis L_(gnp)of the grip section P2. However, as in a connector 325 shown in FIG. 13,the central axis L_(LG) of the light guide part 31, which protrudes fromthe front surface 32, may be made to be coincident with the central axisL_(grip) of the grip section P2 by the change of the disposition or thelike of the pump connection portion 38 and the light guide part 31.

What is claimed is:
 1. A connector for an endoscope that is connected toa light source device generating illumination light, the connectorcomprising: a light guide part that guides the illumination light; awireless communication unit that wirelessly communicates with the lightsource device; a wireless power receiving unit that receives powerwirelessly supplied from the light source device; a housing sectionwhich houses the wireless communication unit and the wireless powerreceiving unit and in which the light guide part protrudes from a frontsurface thereof positioned close to the light source device in aconnection posture where the connector is connected to the light sourcedevice; and a grip section that includes a concave finger placingportion on which a thumb is placed and which is provided on a centralaxis of the light guide part in a case in which the grip section isviewed from an upper surface of the connector positioned on a verticallyupper side in the connection posture.
 2. The connector according toclaim 1, wherein a central axis of the grip section is coincident with acentral axis of the light guide part in a case in which the connector isviewed from the upper surface thereof in the connection posture.
 3. Theconnector according to claim 1, wherein the central axis of the lightguide part is offset to the upper surface of the connector in theconnection posture with respect to the central axis of the grip section.4. The connector according to claim 2, wherein the central axis of thelight guide part is offset to the upper surface of the connector in theconnection posture with respect to the central axis of the grip section.5. The connector according to claim 3, wherein the housing section iscapable of housing the wireless communication unit and the wirelesspower receiving unit on a side thereof close to a lower surface of theconnector positioned on a vertically lower side in the connectionposture.
 6. The connector according to claim 1, wherein the grip sectionhas a shape in which a cross-sectional area decreases toward a rearportion thereof opposite to the housing section from a front portionthereof, which is close to the housing section, in the connectionposture.
 7. The connector according to claim 2, wherein the grip sectionhas a shape in which a cross-sectional area decreases toward a rearportion thereof opposite to the housing section from a front portionthereof, which is close to the housing section, in the connectionposture.
 8. The connector according to claim 3, wherein the grip sectionhas a shape in which a cross-sectional area decreases toward a rearportion thereof opposite to the housing section from a front portionthereof, which is close to the housing section, in the connectionposture.
 9. The connector according to claim 4, wherein the grip sectionhas a shape in which a cross-sectional area decreases toward a rearportion thereof opposite to the housing section from a front portionthereof, which is close to the housing section, in the connectionposture.
 10. The connector according to claim 1, wherein a lower surfaceof the housing section, which is positioned on the vertically lower sidein the connection posture, is a flat surface.
 11. The connectoraccording to claim 2, wherein a lower surface of the housing section,which is positioned on the vertically lower side in the connectionposture, is a flat surface.
 12. The connector according to claim 3,wherein a lower surface of the housing section, which is positioned onthe vertically lower side in the connection posture, is a flat surface.13. The connector according to claim 5, wherein a lower surface of thehousing section, which is positioned on the vertically lower side in theconnection posture, is a flat surface.
 14. The connector according toclaim 6, wherein a lower surface of the housing section, which ispositioned on the vertically lower side in the connection posture, is aflat surface.
 15. The connector according to claim 1, wherein an uppersurface of the housing section, which is positioned on the verticallyupper side in the connection posture, is a curved surface.
 16. Theconnector according to claim 1, wherein the wireless communication unitis capable of performing near-infrared communication between the lightsource device and itself.
 17. The connector according to claim 1,wherein a front surface of the connector where the wireless powerreceiving unit receives power supplied from the light source device hasa structure in which a gap is formed between the front surface of theconnector and a contact surface of the light source device in a case inwhich the connector is connected to the light source device.
 18. Theconnector according to claim 1, wherein the housing section houses thewireless power receiving unit so that the wireless power receiving unitcomes into contact with the upper surface of the connector in theconnection posture, and the wireless power receiving unit is capable ofreceiving power supplied from the light source device through the uppersurface of the connector in the connection posture.
 19. The connectoraccording to claim 18, wherein in a case in which the light sourcedevice includes an upper flange portion that holds the upper surface ofthe connector in the connection posture, the wireless power receivingunit is capable of receiving power to be supplied through the upperflange portion.
 20. The connector according to claim 1, wherein thecentral axis of the light guide part is coincident with the central axisof the grip section in a case in which the connector is viewed from aleft side surface or a right side surface thereof in the connectionposture.